Committee for Specifications for the Design of Committee/Subcommittee Ballot: CS08-306A

Cold-Formed Steel Structural MembersAttachment A-Final

Subcommittee 10, Element Behavior and Direct StrengthDate: February 20, 2009

SPECIFICATION

APPENDIX 1:Design of Cold-Formed Steel Structural Members Using the
Direct Strength Method

1.1GeneralProvisions

1.1.1Applicability

The provisions of this Appendix shall be permitted to be used to determine the nominal axial (Pn) and flexural (Mn) strengths [resistances] of cold-formed steel members. Sections 1.2.1 and 1.2.2 present a method applicable to all cold-formed steel columns and beams. Those members meeting the geometric and material limitationscriteria of Section 1.1.1.1 for columns and Section 1.1.1.2 for beams have been pre-qualified for use, and the calibrated safety factor, ,and resistance factor, , given in 1.2.1 and 1.2.2 shall be permitted to apply. The use of the provisions of Sections 1.2.1 and 1.2.2 for other columns and beams shall be permitted, but the standard and  factors for rational engineering analysis (Section A1.1(b) of the main Specification) shall apply. The main Specification refers to Chapters A through G, Appendices A and B, and Appendix 2 of the North American Specification for the Design of Cold-Formed Steel Structural Members.

Currently, the Direct Strength Method provides no explicit provisions for members in tension, shear, combined bending and shear, web crippling, combined bending and web crippling, or combined axial load and bending (beam-columns). Further, no provisions are given for structural assemblies or connections and joints. As detailed in main Specification, Section A1.1, the provisions of the main Specification, when applicable, shall be used for all cases listed above.

It shall be permitted to substitute the nominal strengths [resistances], resistance factors, and safety factors from this Appendix for the corresponding values in Sections C3.1, C4.1.1, C4.1.2, C4.1.3, C4.1.4, D6.1.1, and D6.1.2 of the main Specification.

For members or situations to which the main Specification is not applicable, the Direct Strength Method of this Appendix shall be permitted to be used, as applicable. The usage of the Direct Strength Method shall be subjected to the same provisions as any other rational engineering analysis procedure, as detailed in Section A1.1(b) of the main Specification:

(1) applicable provisions of the main Specification shall be followed when they exist, and

(2) increased safety factors,  and reduced resistance factors,  shall be employed for strength when rational engineering analysis is conducted.

1.1.1.1Pre-qualified Columns

Unperforated columns that fall within the geometric and material limitations given in Table 1.1.1-1 shall be permitted to be designed using the safety factor, , and resistance factor, , defined in Section 1.2.1.

Columns which fall outside the geometric and material limitations of Table 1.1.1-1 shall be permitted to still use the  or  of Section 1.2.1 if through the use of Chapter F of the main Specification the predicted  from Chapter F provides an equal or higher  (equal or higher level of reliability) to that of Section 1.2.1. In the use of Chapter F, the professional factor, P, shall be the test-to-predicted ratio where the prediction is that of the Direct Strength Method expressions of Section 1.2.1, Pm is the mean of P and Vp the coefficient of variation of P. At least three tests shall be conducted. If Vp is less than or equal to 15%, Cp shall be permitted to be set to 1.0.

Table 1.1.1-1
Limits for Pre-qualified Columns*

Lipped C-Sections
Simple Lips:

Complex Lips:
/ For all C-sections:
ho/t < 472
bo/t < 159
4 < D/t < 33
0.7 < ho/bo < 5.0
0.05 < D/bo < 0.41
 = 90
E/Fy > 340 [Fy < 86 ksi (593 MPa or 6050 kg/cm2)]
For C-sections with complex lips:
D2/t < 34
D2/D < 2
D3/t < 34
D3/D2< 1
Note:
a) 2 is permitted to vary (D2 lip is permitted to angle inward, outward, etc.)
b) 3 is permitted to vary (D3 lip is permitted to angle up, down, etc.)
Lipped C-Section with Web Stiffener(s)
/ For one or two intermediate stiffeners:
ho/t < 489
bo/t < 160
6 < D/t < 33
1.3 < ho/bo < 2.7
0.05 < D/bo < 0.41
E/Fy > 340 [Fy < 86 ksi ( 593 MPa or 6050 kg/cm2)]
Z-Section
/ ho/t < 137
bo/t < 56
0 < D/t < 36
1.5 < ho/bo < 2.7
0.00 < D/bo < 0.73
 = 50
E/Fy > 590 [Fy < 50 ksi ( 345 MPa or 3520 kg/cm2)]
Rack Upright
/ See C-Section with Complex Lips
Hat
/ ho/t < 50
bo/t < 20
4 < D/t < 6
1.0 < ho/bo < 1.2
D/bo = 0.13
E/Fy > 428 [Fy < 69 ksi ( 476 MPa or 4850 kg/cm2)]

Note:*r/t < 10, where r is the centerline bend radius

bo=overall width;D =overall lip depth;t=base metal thickness;ho=overall depth

1.1.1.2Pre-qualified Beams

Unperforated beams that fall within the geometric and material limitations given in Table 1.1.1-2 shall be permitted to be designed using the safety factor, , and resistance factor, , defined in Section 1.2.2.

Beams which fall outside the geometric and material limitations of Table 1.1.1-2 shall be permitted to still use the  or  of Section 1.2.1 if through the use of Chapter F of the main Specification the predicted  from Chapter F provides an equal or higher  (equal or higher level of reliability) to that of Section 1.2.1. In the use of Chapter F, the professional factor, P, shall be the test-to-predicted ratio where the prediction is that of the Direct Strength Method expressions of Section 1.2.2, Pm is the mean of P and VP the coefficient of variation of P. At least three tests shall be conducted. If VP is less than or equal to 15% then CP is permitted to be set to 1.0.

Table 1.1.1-2
Limitations for Pre-qualified Beams*

C-Sections
Simple Lips:

Complex Lips:
/ For all C-sections
ho/t < 321
bo/t < 75
0 < D/t < 34
1.5 < ho/bo < 17.0
0 < D/bo < 0.70
44 < 90
E/Fy > 421 [Fy < 70 ksi (483 MPa or 4920 kg/cm2)]
For C-sections with complex lips:
D2/t < 34
D2/D < 2
D3/t < 34
D3/D2< 1
Note:
a) 2 is permitted to vary (D2 lip is permitted to angle inward or outward)
b) 3 is permitted to vary (D3 lip is permitted to angle up or down).
Lipped C-Sections with Web Stiffener
/ ho/t < 358
bo/t < 58
14 < D/t < 17
5.5 < ho/bo < 11.7
0.27 < D/bo < 0.56
 = 90
E/Fy > 578 [Fy < 51 ksi (352 MPa or 3590 kg/cm2)]

Table 1.1.1-2
Limitations for Pre-qualified Beams(Continued)

Z-Sections
Simple Lips:

Complex Lips:
/ For all Z-sections:
ho/t < 183
bo/t < 71
10 < D/t < 16
2.5 < ho/bo < 4.1
0.15 < D/bo < 0.34
36 <  < 90
E/Fy > 440 [Fy < 67 ksi (462 MPa or 4710 kg/cm2)]
For Z-sections with complex lips:
D2/t < 34
D2/D < 2
D3/t < 34
D3/D2 < 1
Note:
a) 2 is permitted to vary (D2 lip is permitted to is permitted to angle inward, outward, etc.)
b) 3 is permitted to vary (D3 lip is permitted to angle up, down, etc.)
Hats (Decks) with Stiffened Flange in Compression
/ ho/t < 97
bo/t < 467
0 < ds/t < 26(ds =Depth of stiffener)
0.14 < ho/bo < 0.87
0.88 < bo/bt < 5.4
0 < n  4 (n = Number of compression flange stiffeners)
E/Fy > 492 [Fy < 60 ksi ( 414 MPa or 4220 kg/cm2)]
Trapezoids (Decks) with Stiffened Flange in Compression
/ ho/t < 203
bo/t < 231
0.42 < (ho/sin)/bo < 1.91
1.10 < bo/bt < 3.38
0 < nc 2 (nc = Number of compression flange stiffeners)
0 < nw 2 (nw = Number of web stiffeners and/or folds)
0 < nt 2 (nt = Number of tension flange stiffeners)
52 < 84 (Angle between web and horizontal plane)
E/Fy > 310 [Fy < 95 ksi (655 MPa or 6680 kg/cm2)]

Note:

*r/t < 10, where r is the centerline bend radius.

See Section 1.1.1.1 for definitions of other variables given in Table 1.1.1-2.